On-machine backplane mounted modular power and data distribution system

ABSTRACT

A backplane configuration is described for supporting a range of modular components mechanically and for making electrical connections between the components. The backplane is particularly well-suited to power distribution and control applications, such as in industrial motor drives, and so forth. The backplane includes a number of bays or slots for modular components, as well as a bus topography that allows for switched or common connections between the various components.

BACKGROUND

The present invention relates generally to electrical control andmonitoring systems, such as systems used in industrial and otherelectrical power applications. More particularly, the invention relatesto a technique for mounting and interfacing of power control devices,particularly well-suited to use at or near a driven or powered load.

A wide range of applications exist for applying and controllingelectrical power in industrial, marine, agricultural, commercial andother settings. The many such applications, a powered load, such as anelectric motor, is provided with single or three-phase electrical power.The power originates in the power grid, and is channeled to theapplication through various distribution circuits and, ultimately,protective circuitry and switch gear at or near the load. In industrialapplications, for example, motors have traditionally been controlledthrough a range of devices that are mounted in and interlinked in largeelectrical enclosures or cabinets, typically called motor controlcenters (MCC).

A growing alternative to MCCs involves the separation of powerdistribution, control and monitoring circuitry to locate individual anddistributed systems near the actual loads that they control. Forexample, an industrial setting, many motors and other actuators may becontrolled for a particular machine process. On-machine systems arebeing designed to control one or a handful of such motors viadistributed systems located near the individual motors and mounted to amachine frame. Such applications, while potentially reducing costs andimproving local control, pose substantial difficulties. For example, theon-machine environments are often subjected to considerable vibrationand environments around the machine systems are potentially lesscontrolled than are those in a central enclosure. However, the benefitsof local control, reduced wiring costs, and decentralization offunctionality help to drive such solutions.

Existing on-machine control and monitoring systems are generallypackaged as a pre-designed unit. That is, all necessary drives, drivecircuitry, protective circuitry, switch gear and the like are includedin a packaged enclosure. While such solutions are workable, furtherimprovements are believed useful. For example, there is a need in theart for systems that will facilitate a modular approach to selection andinterfacing of protective circuitry, drive circuitry, switchgear, andthe like. Similarly, there is a need for a system that will permitenvironmentally-controlled electrical interfacing in a package that canbe expanded or contracted to meet the local power distribution andcontrol needs.

BRIEF DESCRIPTION

The present invention provides a novel approach to on-machine controland monitoring systems designed to respond to such needs. The inventionmay be used with a wide range of machines and applications, and isparticularly well-suited to industrial applications, such as forcontrolling loads and actuators, particularly electrical motors. Thetechnique is based upon the provision of a powered backplane designed tomechanically support and electrically interface a range of components.The components may include any suitable protective circuitry, switchgear, drives, and so forth. The circuitry may also include input/output(I/O) interfaces for sensors and actuators, and so forth.

The backplane is made so as to provide bays or locations at which thedevices, which will typically be designed as modular units, can beinstalled and sealed, thereby enclosing an environment both within themodules and the backplane. The backplane provides for distribution ofpower and data signals, enabling the devices to be interfaced with anetwork. The distribution of power in the backplane can follow varioustopologies, so as to permit interruption of power to downstreamcomponents, such as via modular protective circuitry, while allowingcertain components to share common service, such as for control powerand data. The backplanes can also be designed or associated with otherbackplanes to provide parallel and independent power and control ofdifferent loads, such as various motors at or near a particular machinelocation.

DRAWINGS

These and other features, aspects, and advantages of the presentinvention will become better understood when the following detaileddescription is read with reference to the accompanying drawings in whichlike characters represent like parts throughout the drawings, wherein:

FIG. 1 is diagrammatical representation of a control and monitoringsystem incorporating a power backplane in accordance with aspects of thepresent technique;

FIG. 2 is diagrammatical representation of a backplane for the system ofFIG. 1 illustrating bays or locations, and control and monitoringmodules that can be located at the various positions to create thedesired load control and monitoring system;

FIG. 3 is an exemplary wiring topology for a backplane of the type shownin FIG. 2, illustrating an exemplary manner in which power may be routedwithin the backplane to provide for switching of power for applicationto a load, and common service for control power and data; and

FIG. 4 is a diagrammatical representation of a backplane wiring topologysimilar to that of claim 3, but illustrating a manner in which multiplebackplanes or backplane areas can be associated with one another so asto provide for independent monitoring and control of multiple loads at asingle location.

DETAILED DESCRIPTION

Turning now to the drawings, and referring first to FIG. 1, a controland monitoring system is illustrated and designated generally byreference numeral 10. System 10 includes various components for applyingelectrical power to a machine system, represented generally at referencenumeral 12. As will be appreciated by those skilled in the art, themachine system 12 may be any of a wide range of machines systems thathave powered loads and points at which certain sensed data is collectedfor control and monitoring purposes. Examples of such machines systemsin industrial settings might include manufacturing processes, assemblylines, material handling and conveyers, chemical process controls, fluidhandling systems, and so forth. The present techniques are not intendedto be limited to any particular type of machine system.

The control and monitoring system 10, as illustrated, includes a rangeof local controllers 14 and 16 that are located in the general vicinityof points where power is applied to the machine system 12 or where datais collected. The local controllers 14 and 16 may carryout a wide rangeof functions, such as for starting and stopping loads, such as electricmotors, regulating application of power to the loads, sensingapplication of power to the loads, sensing parameters of the process towhich the loads are applied, and so forth. In the illustrated example,local controller 14 controls a motor 18, and interfaces with a pair ofsensors 20. The sensors may, for example, sense the performance of themotor 18 or may sense other machine parameters, such as elevations,speeds, vibration, the presence of a work piece, and so forth, to nameonly a few. Similarly, local controller 16 controls application andpower to a motor 22, and interfaces with a sensor 24. As will beappreciated by those skilled in the art, many such controllers may beprovided in a typical large machine system or process, and each localcontroller may be interfaces with a range of actuators and sensors. Thesystem also includes stand-alone I/O modules as illustrated at referencenumeral 26 that may be used to interface with other actuators andsensors, such as sensor 28.

The controllers 14 and 16, and I/O module 26 are coupled to power anddata busses that provide for application of power to the loads,provision of control power, and exchange of network data. In theillustrated embodiment, a data bus 30 is coupled to each of thecontrollers and I/O module to exchange sensed and control data inaccordance with a suitable protocol. By way of example, in an industrialsetting, known protocols might include the DeviceNet protocol. A controlpower bus 32 is provided and coupled to the controllers for providingcontrol power. As will be appreciated by those skilled in the art,control power generally is either ac or dc power (e.g., 110vac or 24vdc)that enables switching devices, actuators, and sensors to perform theirtasks.

In general, in many applications it is desired to provide control powerthat can be independently switched from the power applied to the loads,permitting testing and servicing of the controllers without poweractually being applied to the loads. Similarly, a power bus 34 isprovided for distribution of the power to be applied to the loads. In atypical industrial setting, the power bus will include four conductorsfor three-phase power and a ground. A neutral conductor may also beprovided in the bus, were desired. The invention is not, however,limited to the application of three-phase power, but is equallyapplicable to systems distributing single-phase power.

In certain settings, a supplementary bus which may be referred to as anE-stop bus, represented by the dashed line capital S may also beprovided. As will be appreciated by those skilled in the industrialarts, E-stop circuits (a term coined to refer to “emergency stop”circuits) are provided for interrupting power to certain loads in theevent of the need for a rapid removal of power. In many settings, anE-stop bus will be interfaced with conspicuous push buttons to allowpersonnel to positively stop a process when needed.

While the local controllers may generally function virtually completelyindependently, in many settings it may be desirable to convey controland monitoring signals between these controllers and remote control andmonitoring equipment. For example, in an industrial setting, suchequipment may include programmable logic controllers, remote computersystems, various associated controllers in control rooms or controllocations, and so forth. One such remote control and monitoring system36 is illustrated in FIG. 1 as coupled to the data bus 30 and to thecontrol power bus 32. As will be appreciated by those skilled in theart, such monitoring and control equipment may include operatorinterfaces 38 of various types. Such operator interfaces may includeconventional computer monitors, keyboards, by-hand input devices, andthe like. In certain settings, moreover, the interfaces will includehuman machine interfaces (HMIs) dedicated for the particular process tobe controlled. It should be also noted that such operator interfaces maybe provided at each local controller 14 and 16, where desired.

FIG. 2 illustrates an exemplary backplane configuration for use in alocal controller such as controller 14 or 16 of FIG. 1. As shown, thebackplane 40 will comprise a rigid mechanical structure, such as a thinmetal enclosure, plastic enclosure, or a composite assembly which willdefine bays or locations 42 for locating module components. In anexemplary implementation, the backplane will be isolated from vibrationon a machine frame via shock absorbing materials that can be mountedbetween the machine frame and the backplane. Such shock absorbingmaterials may include rubber grommets, a shock absorbing layer or sheet,and so forth. The backplane extends over an area to be occupied by thecomponents, and may arrange the bays horizontally, vertically, or in acombination of patterns and topographies. The backplane may be made instandard dimensions, and where no modular component is place in aparticular bay, such bays may be covered and sealed. Where desired,multiple sizes or configurations of the backplanes may be made, such asto accommodate various anticipated typical system configurations, systemdimensions, and the like. Similarly, extensions, represented generallyby reference numeral 44 may be provided for accommodating additionalcomponents, I/O modules, and independently operated system components asdescribed in greater detail below.

In a presently contemplated embodiment, the modular components aredesigned to control and monitor application of electrical power toloads, such as, by way of example, electric motors. The componentsgenerally are designated in FIG. 2 by the reference numeral 46. Atypical application may include a modular circuit protector ordisconnect 48, a contactor 50, an E-stop module 52, and a safety relay54. As will be appreciated by those skilled in the art, such componentswill typically be placed in a set or predetermined order depending upontheir function in the overall system. For example, a disconnect andfuses as illustrated for module 48 will typically be placed electricallyupstream of the contactor 50. The arrows in FIG. 2 illustrate, however,that in certain applications there can be some degree of freedom as towhich bay the individual modules occupy. Where applicable, for example,a contactor may be placed downstream of a fused disconnect but upstreamof or adjacent to a safety relay such as illustrated at referencenumeral 54. The various components occupying the bays 42 will generallyhave their same function and may be based upon existing components inthe art. However, their configuration and packaging is such that theycan be mounted on, mechanically supported on, and electricallyinterfaced with the backplane 40.

In a presently contemplated embodiment, in addition to the protectivecomponents and switchgear components mentioned above, the backplane 40can support a range of drives or control devices. In the illustratedembodiment, for example, these may include a direct across-the-linestarter 56, a variable frequency drive 58, a smart motor controller 60and a reversing motor starter 62. In the presently contemplatedembodiments, such components would be configured to be placed in andinterface with the backplane and the remaining components in a modularmanner. That is, packaging for each of the components for driving amotor in accordance with various specifications and needs may beinterchangeable such that a system may use the same backplane and manyof the same modular components, with the control or drive elements beingselected according to the application. It should also be noted thatbecause the backplane 40 will be configured for mounting locally to amonitored or controlled point in a machine system, as indicated by alocal controller 14 and 16 in FIG. 1, power to the ultimate load may beprovided by either shielded cable, multi-conductor cable, or conduit. Ina presently contemplated embodiment, for example, a flexible cable,designated generally by the reference C in FIG. 2, is connected to thedrive or control module and extends to the application.

In addition to the foregoing components, it is presently contemplatedthat the on-machine backplane 40 will accommodate various interfaces forinput and output devices, such as actuators and sensors. In theembodiment illustrated in FIG. 2, a generally horizontal row of suchinterfaces may be provided at I/O slots or bays 64. By way of example,local I/O 66 may be interfaced with both the network and, whereappropriate, the control power busses and with other components mountedon the backplane 40. Similarly, expansion I/O 68 may be provided inadditional slots or bays and similarly interfaced with the network. Thearrangement, then, allows for both the local and monitoring ofprocesses, and the support of other actuator and sensor interfaces in anintegrated unit.

FIG. 3 illustrates an exemplary connection topology for an on-machinebackplane 40 of the type described above. As noted above, the backplanewill typically permit switched connections to be made, particularly forthe power applied to loads, while certain common service will beprovided for some or all of the bays or slots. In the embodimentillustrated in FIG. 3, for example, the backplane 40 includes a seriesof cut-outs or openings at which the modular components are mounted. Themodular components may be attached to the backplane so as to fitgenerally in a conforming periphery 70, with attachment being providedby lugs or screw attachments as indicated generally at reference numeral72. Other mechanisms for attachment may, of course, be provided, such assnap-in and pluggable attachments, brackets, and so forth. The presentlycontemplated backplane also will allow for sealing between each of thecomponents and the backplane, to enclose the interior of the backplaneand any space between or within the components and the backplane. Suchsealing will typically be made within or immediately adjacent to theperiphery 70 of each bay.

Within the backplane, and as indicated diagrammatically in FIG. 3, arouting topography for conductors or busses will correspond to thelogical use made of the module components, either switched or common.That is, as illustrated at reference numeral 74 in FIG. 3, busses willbe typically terminated at terminals 74 and routed between suchterminals to convey power between or among the bays. The terminals maypermit either terminated or plugged-in attachment of the modularcomponents within the bay to facilitate their termination andinstallation, as well as their removal for maintenance and replacement.

In the example illustrated in FIG. 3, common service busses mightinclude data bus conductors 76 which convey data to all bays and thatwill be ultimately terminated to network media as discussed above withreference to FIG. 1. Similarly, common service may include control powerconductors 78 that route control power to all bays where such power maybe needed. Of course, where a modular component does not require controlpower or data, the busses may nevertheless be present in the backplane,but no connection made to the components.

As will be appreciated by those skilled in the art, E-stop connectionstypically allow for emergency stopping or interruption of power by anyone of a variety of components. Thus, a topography for E-stop busses,indicated generally at reference numeral 80 in FIG. 3, may provide for acommon conductor and separate conductors so that a complete loop circuitcan be defined by all of the modular components and interruptionpermitted by any one of the components.

Similarly, the three-phase power conductors 82 illustrated in FIG. 3will typically allow for switching or interruption by a variety ofcomponents. For example, a master disconnect and fuses may be providedin a first module and interfaced so as to permit interruption of powerto all downstream components. Similar separate busses may be terminatedand coupled to contactors, for example, at an intermediate position toallow the contactor to make and break connections downstream so as toisolate the downstream circuitry where desired. Similar separated busseswill typically be provided for E-stops, safety relays, and so forth.

FIG. 4 represents a variant on the arrangement shown in FIG. 3,particularly adapted for a multi-unit backplane 84. The backplane 84 isillustrated diagrammatically to demonstrate how certain connections canbe made to permit components and systems to be co-located whileoperating independently. In the illustrated example, for example, afirst modular backplane 86 is associated with a second modular backplane88. In practice, the two backplanes may form a single unit but providefor separate operation of motors, actuators, and other loads. In theillustrated embodiment an incoming power expansion bay 90 is providedfor a fused disconnect that supplies power to the entire multi-unitbackplane 84. Downstream of this fused disconnect bay, terminations aremade to the first slot or bay of backplane 86, and power jumpers 92route power to a first slot or bay of backplane 88. Thus, a variety ofmodular components can be mounted and supported on each of thebackplanes, and supply power to loads completely independently of oneanother. Topographies for routing of power and data within thebackplanes can be generally similar to that described above withreference to FIG. 3.

While only certain features of the invention have been illustrated anddescribed herein, many modifications and changes will occur to thoseskilled in the art. It is, therefore, to be understood that the appendedclaims are intended to cover all such modifications and changes as fallwithin the true spirit of the invention.

1. An on-machine modular electrical monitoring and control systemcomprising: a backplane configured to mechanically support a pluralityof system components; switchable power buses disposed on or in thebackplane for carrying three-phase switched electrical power; commonservice buses disposed on or in the backplane for carrying control powerand data signals; a switchable power module pluggable to the backplanefor establishing an interruptible three-phase current path between theswitchable power buses; and a motor control module pluggable to thebackplane and receiving three-phase electrical power via the switchablepower module, and power and data signals via the common service buses;wherein the backplane is configured to support a plurality ofindependently operating switchable power modules and motor controlmodules.
 2. The system of claim 1, wherein the switchable power moduleincludes an overload protection module.
 3. The system of claim 1,wherein the switchable power module includes a circuit breaker.
 4. Thesystem of claim 1, wherein the switchable power module includes a manualdisconnect.
 5. The system of claim 1, wherein the switchable powermodule includes a remotely controlled relay.
 6. An on-machine modularelectrical monitoring and control system comprising: a backplaneconfigured to mechanically support a plurality of system components;switchable power buses disposed on or in the backplane for carryingthree-phase switched electrical power; at least one common service busdisposed on or in the backplane for carrying control power and datasignals; a switchable power module pluggable to the backplane forestablishing an interruptible three-phase current path between theswitchable power buses; and a motor control module pluggable to thebackplane and receiving three-phase electrical power via the switchablepower module, and power and data signals via the common service buses;wherein the backplane is configured to support a plurality ofindependently operating switchable power modules and motor controlmodules.
 7. The system of claim 6, wherein the switchable power moduleincludes an overload protection module.
 8. The system of claim 6,wherein the switchable power module includes a circuit breaker.
 9. Thesystem of claim 6, wherein the switchable power module includes a manualdisconnect.
 10. The system of claim 6, wherein the switchable powermodule includes a remotely controlled relay.
 11. An on-machine modularelectrical monitoring and control system comprising: a backplaneconfigured to mechanically support a plurality of system components;switchable power buses disposed on or in the backplane for carryingthree-phase switched electrical power; at least one common service busdisposed on or in the backplane for carrying control power and datasignals; a switchable power module coupled to the backplane forestablishing an interruptible three-phase current path between theswitchable power buses; and a motor control module coupled to thebackplane and receiving three-phase electrical power via the switchablepower module, and power and data signals via the common service buses;wherein the backplane is configured to support a plurality ofindependently operating switchable power modules and motor controlmodules.
 12. The system of claim 11, wherein the switchable power moduleincludes an overload protection module.
 13. The system of claim 11,wherein the switchable power module includes a circuit breaker.
 14. Thesystem of claim 11, wherein the switchable power module includes amanual disconnect.
 15. The system of claim 11, wherein the switchablepower module includes a remotely controlled relay.